Regulating system for storage batteries



B. s. WEAVER ET AL REGULATING SYSTEM FOR STORAGE BATTERIES Filed Jan. 21, 1944 AHF VLF VRF Patented Dec. 11, 1945 anomrmo SYSTEM Iron s'roaaor.

aarraams Burr S. Weaver, Scotia, and Donald E. Garr, Schenectady, N. Y., asslgnor to General Electric Company, a corporation 0! New York Application January 21, 1944, Serial No. 519,l56

14 Claims.

Our invention relaiesto regulating systems for storage batteries and particularly to systems for regulating the charging current and the dischargins current of a storage battery which is employed as a standby power source. s

In many electrical installations, it is very essential that there be provided a secondary or standby source of'power which is at all times ready to supply power to a load circuit in case the main source 01 supply for the load circuit 10 fails. It is quite commonwhere the power is direct current to provide a standby storage battery which is normally arranged to be charged from the main source as long as the main power source is operative to supp y power'to the load circuit iii and which is arranged to supply power immediately to the load circuit in casethe main power source fails. This result is usually accomplished by providing a direct current dynamoelectric machine in series with the battery and regulating the excitation of this series connected machine so as to maintain the proper charging voltage across the battery while it is being charged from the main power source and so as to maintain the proper voltage across the load circuit when as it is being supplied irom the battery.

One object of our invention is to provide an improved regulating system for such a series connected dynamoelectric machine, between a battery and a load circuit, which is fast and accurate 39 in operation, has no contact mechanisms or sensitively balanced armatures, and is free from excessive maintenance.

Our invention will be better understood from the following description when taken in connec- 86 tion with the accompanying drawing, the single figure of which diagrammatically illustrates a standby storage battery regulating system embodying our invention, and the scope of our invention will be pointed out in the appended to claims. I

In the accompanying drawing, I represents a direct current load circuit which is arranged to be supplied normally with electric energy at a constant voltage: from a primary source of direct 45 current 2, shown as a direct current power circuit which is arranged to be connected across the load circuit I by means of a suitable switch 3. As shown, this switch 3 is arrangedto connect the positive sides of the circuits I and 2 together, it 60 being assumed that the negative'sides of the two circuits ar permanently connected together. A

suitable standby storage battery 4 is also arranged to be connected across the load circuit I 1 by means of a manually controlled line switch 55 circuit 2.

BLS, which is connected between the positive terminal of the battery 4 and'the pomtive side of the load circuit I. The negative terminal of the battery 4 is shown as being permanently connects ed to the negative side of the load circuit I. The flow of current between the battery 4' and the load circuit I is controlled by means of a direct current dynamoelectrlc machine I, the armature winding of which is connected between the positive terminal of the battery 4 and the positive side of the load circuit I. As shown, the direct current machine 5 is driven by a shunt wound direct current motor 6, which is arranged to be connected across the load circuit I by means of a suitable switch I and a conventional starter, not shown, whereby the motor may be started from rest and brought up to its normal operatin! speed. Y v

The switch 3 is normally arranged to be closed 20 when an associated manually controlled switch 8 is closed and the voltage of the primary source 2 is within a predetermined range and is arranged to be opened when either the associated control switch 8 is open or the voltage of the primary source 2 decreases to such a low value that current flows from the battery I to the primary source 2. As shown, the switch Iis providd with an operating winding I! which is arranged to be connected across the primary supply circuit 2 by means of a circuit that includes in series the contacts II oi the controlswitch 8 when it is closed, the contacts I2 of a normal voltage relay NVR which is connected across the supply circuit 2 so as to close the contacts I2 when the supply circuit voltage is'sllghtly below its normal operating voltage, the contacts I l of an overvoltage relay OVR which is connected across the supply circuit 2 so as to open the contacts I3 when the supply circuit voltage is in excess of the maximum voltage allowable at the closing of the switch 3, and the contacts ll of a line relay LR which is arranged to be energized from the supply circuit 2 when the control switch 8 is closed, the supply circuit voltage is within the proper operating range, and no current is flowing from the battery 4 to the supply circuit 2. The energizing circuit of the line relay LR includes the contacts I5 o1 a suitable reverse current relay RC, which is arranged in any suitable manner'so that it opens its contacts I! when current flows from the battery I to the supply As shown in the drawing, the reverse current relay RC is provided-with a current winding I 6, which is connected-between the positive terminals of the supply circuit 2 and the battery regulating field means of the contacts '26 of the relay CR to the 7 sisters RHVB, one terminal of the resistor RHVR is connected 4 when theswitch 3 is closed, and with a voltage winding H, which is arranged to be connected across the supply circuit 2 by the contacts ill of a control" relay CR, the operating winding of which is connected across the supply circuit 2 by the contacts IQ of the switch 3 when it is closed.

For controlling the direction and magnitude of the voltage of the direct current machinei so as to vary the flow of current to and from the battery 4 in the desired manner, we provide, in accordance with our invention, a direct current exciter 20 of the well-known armature reaction excited type, commonly known as an amplidyne exciter, which has its output brushes connected to the field winding 2| of the direct current machine 5. The exciter 20 may be driven by any suitable constant speed driving means, such as the shunt motor 6, and is provided with the usual series compensating field windings 22 and 23 and the anti-hunt shunt field winding AHF, which hasa suitable condenser 24 connected in the cir cuit thereof.

" when .the primary source 2 is supplying cur-' rent to the load circuit I, it is desirable to charge the battery 4 from the supply circuit 2 so as to maintain the battery'iully charged and to control the charging current in accordance with i the condition of the battery. In the embodiment of the invention shown in the drawing, we ac complish this result by providing the exciter 20 with a voltage regulating field winding VRF field winding 2| Of-the' machine 5 in such a-man ner that the machine 5 generates its maximum voltage and the charging voltage impressed across the battery 4 is equal to the sum of the supply circuit voltage and the voltage of the machine 5.

While we have shown separate resistors RHVR, 29 and 30, it is obvious that they could be a single resistor having a plurality of terminals and adjustable contacts associatedtherewith. There- "fore; in the appendedclaims the term. resistor is employed to cover either a single resistor or a pluralit of separate resistors connected in series.

' -The control of the charging rate is effected by means of a current limiting field winding CLF,

on the exciter 20, which is energized in accord- "ance with thedifierence between a predetermined constant voltage and a voltage that varies whichwhen the control relay CR is' energized,

is energized so that the charging voltage is equal to the sum of the voltage of themachine 5 and ,the supply circuit 2. When the control" relay CR, is energized, one terminal .of the voltage winding VRF is connected by positiveside of the load circuit 1, and the other 9 terminal pot the voltage regulating field 'winding VRF is'connected b means of the contacts 210i the relay CR to an adjustable contact 28 on a resistor'RHVR, which is connected in series with the resistors 29'and 30 across the terminals are constant'voltage direct current generator 3| drivenby the motor 6. 'Thes'eries connected re- 29 and 30 are so arranged that to the positive terminal 01 the constant voltage generator and one terminal of the resistor 30 is connected to the negative terminal of the generator '3l, and the resistor 29 is connected between'the other terminals of the resistors RHVR and 30. Also,the common connection 32 between the resistors 29 and 30 is connected to the negative side of the load circuit I, and the battery} so that'the magnitude and direction of the current through the field windingVRF, when the control relay GR is energized, depends 'upon the difference between the load circuit voltage and voltage drop between the adjustable conings VRF and CLF is decreased toeiiect a de tact 28 'on the resistorRHVR and the common connection 32 which is connected to the negative, side of the load circuit and the battery 4. The contact 28 on the resistor RHVR, is

' the other terminal of the so adjusted that with the supply circuit 2 maine, .taining normal voltage across the load circuit i, the load circuit voltage exceeds the voltage drop between the adjustable contact 2B'and the negative side of the load circuit 2 a suiilcient amount so that the current through the regulating field winding VRF produces an exciting fiux in the proper direction, indicatedby the solid arrow associated therewith, and of proper magnitude to cause the exciterZO to exc te Hit wave rectifier 35', which 5 and thecharging voltage with the magnitude of the charging current. For accomplishing this result in the arrangement shown in the drawing, we provide a resistor 33 in the connection between the negative terminal of the battery 4 and the point where the common connection 32 is connected to the negative side of the load circuit One terminal 0! the 'current'limiting field windingCLF is connected to the negative terminal of the battery 4; and

'the other terminal of the current limiting field that the terminal of theresistor 33 which is connected to the negative terminal of the battery 4 is more positive than the adjustable contact 34 on the resistor 29, Current then flows through the current limiting field winding CLF and the rectifier 35 in such a direction as-to produce a fiux the direction indicated by the solid" arrow associated with the winding CLF so that the net excitation produced by the two field windvoltage generated by the machine impressedacross the crease in the battery 4. v

In order to limit to a predetermined maximum value th charging voltage that can" be applied across the battery 4, we provide the exciter 20 with a voltage limiting field winding-VLF which is arranged to be energized so as to decrease the exciter' 20 when the charging predetermined value. This rethe embodiment shown in net excitation of voltage exceeds a suit is accomplished in the drawing bybonnecting one terminal- 0f thevoltage limiting field winding VLF to the positive terminal of the constant voltage generator SI and voltage limiting field winding VLF to an adju'stablecontact on a resistor RHV, which is permanently connected in series 'withthe armature winding of the machine 5 across the load circuit l, and therefore is connected across the terminals of the battery 4 when the switch BLS is closed. A suitable 41nidirectional current conducting device, suthas a [through the voltage limiting one-wave rectifier-3B, is connected in the circuit of the winding VLF so that current can flow field winding VLF only when the voltage across the resistor R HV is across the resistorsRI-IVR and 29.

resistors RHVR, 29 and 33 so that if the charging voltage tends to exceed this predetermined value, current flows through the voltage limiting winding VLF in a direction to produce a fiux in the direction indicated by the solid arrow associated therewith so as to decrease the net excitation of the exciter and consequently the voltage of the machine 5, which in turn decreases the charging voltage and the charging current.

When the main supply circuit 2 fails and the battery 4 has to supply all of the current to the load circuit I, it is desirable to effect the changeover quickly withoutany material change occurring in the normal operatingvoltage across the load circuit I and to continue to supply current to the load circuit I from the battery 4 as long as any charge remains in the battery, even though the discharge voltage of the battery may decrease below the load circuit voltage. In order to accomplish this result, the control relay CR, when deenergized. changes the connections of the voltage regulating field winding VRF so that it is energized in accordance with the variations in the load circuit voltage relative to the voltage of the constant voltage generator 3i.' In the embodiment of the invention shown in the drawing, one terminal of the voltage regulating field winding VRF is connected to the positive terminal of the generator 3| by the contacts of the control relay CR when it is deenergized, and the other terminal of the voltage regulating field winding VRF is connected by the contacts of the control relay CR when it is deenergized to an adjustable contact on a resistor RHCL, which is connected across the load circuit I. The contact all discharging voltages of the battery 4 in excess of the load circuit voltage.

When the discharging voltage of the battery 4 is below the normal line voltage, the regulating arrangement maintains a load circuit voltage which is slightly lower than the normal operating load circuit voltag so that current flows through the voltage regulating field winding VRFirom the positive terminalof the resistor RHVR to the point 4| and produces an exciting flux in the Y opposite direction to that indicated by the solid H on the resistor RHCL is so adjusted that when only the battery 4 is supplying current to the load circuit i and the battery discharging voltage is substantially equal to the normal load circuit voltage, the voltage between the contact 4| and the negative side of the load circuit is substantially equal to the sum of the voltage drops across the resistors RHVR and 29 so that no current fiows through the field winding VRF. Therefore, when the charge of the battery 4 is such that its discharging voltage is higher than the normal load circuit voltage, the load circuit voltage is maintained at a voltage slightly higher than normal so that the voltage between the contact 4| and the negative side of the load circuit i is also slightly higher than the sum of the voltage drops Since the contact H is at a higher potential than the positive terminal of the generator 3i under such conditions of the battery I, current fiows through the voltage regulating field winding VRF in a direction to produce in the exciter 20 an exciting fiux in the direction indicated by the solid arrow associated therewith so that the voltage generated by the dynamoelectric machine opposes the battery voltage and tends to decrease the load circuit voltage, Consequently, the higher the discharging voltage of the battery 4 is above the normal load circuit voltage, the greater is the opposing voltage of the machine 5 so that the load circuit voltage is maintained substantially constant for arrow associated therewith. Consequently, the direction of the voltage of the machine 5 is such that it is added to the battery voltage and its magnitude is regulated to maintain the load circuit voltag at substantially its normal operating value. Therefore, it will be seen that when the battery 4 is supplying current to the load circuit and the battery voltage decreases from, a value above the load circuit voltagev to a value below the load circuit voltage, the regulating arrangementvaries the excitation ofthe exciter 20 and the machine 5 so that the voltage of each of these machines is gradually decreased from a value in one directioniozero and then is gradually' increased in the opposite direction. l

In order to prevent the current output of the battery 4 from exceeding a predetermined value when it is supplying current to the load circuit, the terminal of the currentlimitingfield winding CLF', which is connected to the adjustable contact 34 on the resistor 29 through the halt-wave rectifier 35, is also connectedto an adjustable contact 43 on the resistor 30 through a suitable unidirectional conducting device,,such as a halfwave rectifier 44, which is so arranged as to allow current to fiow through the current limiting field winding CLF only when suflicient current is supplied by the battery 4 to cause the voltage drop across the resistor 33 to be greater than the voltage drop between the common connection 32 and the adjustable contact 43 onthe resistor 30. Therefore, when current from the battery 4 to the load circuit I exceeds a predetermined value, which depends upon the position of the adjustable contact 43, current flows through the field winding CLF to produce a flux in the opposite direction to that indicated by the solid arrow associated therewith, so as to increase the excitation of exciter 20 and the opposing voltage of the machine 5 when the battery voltage exceeds the load circuit voltage and todecrease the excitation of the exciter 20 and the boosting voltage of the machine 5 when .the battery voltage. is below the load circuit voltage. I

The operation of the regulating arrangement shown in the drawing is as follows: When it is desired to place the regulating arrangement in operation, the control switch is closed to complete across the supply circuit 2 an energizing circuit for the line relay LR through the contacts I] of the control switch 8, the contacts l2 of the 'normal voltage relay NVR, the contacts i3 of the overvoltage relay OVR, and the contacts l5 of the reverse current relay RC. Therefore, it the supply circuit voltage is within a predetermined range, the line relay LR is energized and closes its contacts i4 to complete across the supply circuit 2 an energizing circuit for the operating winding H) of the switch 3 through the previously described series connected contacts ll, l2 and I3.

switch 3 connects the positive side of the supply circuit 2 to the positive side of the load circuit I, and the closing of the auxiliary contacts IQ of The closing of the main contacts of the through the current winding I6 is: from the supply circuit 2- to the load circuit The motor 6' is then started by closing the switch], and arterthe motor Ghas reached its normal operating speed, the voltage regulating winding- VRF is energized in accordance with the 'diflference 'between the load circuit voltage and the voltage drop across the resistors RHVR and 205 'Ih'e'voltageof the'constant voltage machine fl isadiusted so that the voltage drop across the resistorsand 29 is less than the load circult voltage so that the current through the field win'ding'VRF is ina' direction to produce a flux i'n'the direction indicated bythe associated arrow. This-flux causesfthe voltage of the machine to beinsuch'a' directionthat it is added to the voltage of the supply circuit 2 and the voltage impressed'across the resistor RHV is equal to the sum or the voltages of; the machine 5 and the supply circuit 2. Thevoltage or the machine 5 is limited by the position of the adjustable contact 31 on the resistorRH'V because as soon as the voltage between the contact 31 and the negathe charging current exceeds the predetermined maximum value.- a

The position to which the adjustable contact 31 is moved'i's such that when the battery 4 is fully charged the voltage between the adjustable contact 31 and-the common connection 32 is sutficiently high to cause enough current to now through the voltage limiting field winding VLF to reduce the excitation of the exciter 20 and the voltage of the dynamoelectric machine 5 to such a value that the charging current 'is decreased to a predetermined .small value. Since this small chargingcurrent flows through the resistor 33 in such a direction 'that'an increase in the charging current increases the drop between the adjustable contact 31 and-the common connection 32,-and thereby effects an increase in I the excitation of the opposing voltagelimiting field winding VLF and a decrease in the net excitation of the exciter 20 .and in the voltage of the dynamoelectric machine 5, and a decrease in this small charging current decreases the excitationof the'opposing voltage limiting field winding VLF, and thereby eil'ects an increasein the net excitation of the exciter 20 and in the voltage of the dynamoelectric machine 5, the regutive side of the supply circuit-2 exceeds the voltage drop across theresistorsRHVR, 29 and 33, current fiows through the voltage limiting field winding VLF in a direction to produce a flux in the direction indicated'by the associated arrow which decreases the net'excitation oi the exciter 20 and the voltage of the machine 5' so' as to decrease the voltage'rmpressed across the resistor The'position-of the adjustable contact 31 is then varied to cause the voltage across the resistor RHV'to' be the same as the terminal voltage of the disconnected battery 4, and then the battery lineswitch BLS is' closed, after which the adjustable contact 31 is so positioned that no current fiows'through the voltage limiting field winding VLF until the charging voltage across the battery 4 reachesa predeterr'ninedvalue.

a It will'be noted that the charging current produces across the resistor 33 a voltage drop which is in such a direction that when the charging current exceeds a predetermined maximum value, current flows through the current limiting field winding CLF'and the hali wave rectifier 35 in a direction to produce a flux in the direction indicated by the associated arrow so as to decrease the net excitation'produced by'the'exciter field windings VRF and'CLF and thereby decrease the voltage of. the dynamoelectricmachine 5 sufilciently to prevent the charging currentfrom exceeding the predetermined maximum value. The current that fiows through the current limiting field winding CLF also flows through that portion or the resistor 29 between the adjustable contact 34 and the common connection 32 in such a direction as to effect an increase in the voltage drop across this portion of the circuit connected to the constant voltagegenerator 3| and, consequently, an increase in the voltage drop across the resistors RHVR and 29. Therefore, the voltage impressed across the voltage regulating winding VRF and the current therethrough are also reduced to decrease the charging voltage when lating arrangement maintains the small charging current substantially constant at a predetermined value dependent upon the position of the'adiust- I able contact 31.

Let it now be assumedthat while. the battery 4 is being charged, the main supplycircuit voltage rails, so that the load. circuiti is supplied fromithebattery 4 and current also flows rrom the battery 4 to the supply. circuit 2 through the current winding 16 of the reverse current relay RC 50 that the contacts |5.of this relayareopened to effect the deenergization oi the line relay LR. The opening ofthe' contacts I4 or the relayLR effects the deenergization of the line switch 3 and the control .relay CR so that the supply circuit 2 is disconnected from the load circuit and the battery 4 .and so, that theconnections of the voltage regulating field winding VREof the exciter 20 are changed .to cause this field winding tovbe energized in accordance with variations in the load circuit voltage. 1 I

The position ofthe adjustable contact 4| on the resistor RHCL is such that when the battery 4 is fully charged the voltage drop across the resistors RHVR and 29, is less than the voltage drop between the adjustable contact and the common connection 32 so that current flows from the adjustable contact 4| through the voltage regulating field winding VRF to the positive, terminal of the resistor RHVR. This current is in a direction to excite the exciter 20 in such a manher that the voltage of the dynamoelectric machine 5 opposes the terminal voltage of the battery 4. The positiorioi the contact 4| on the resistor RHCL is such that when the battery is fully charged and a predetermined voltage existsacross the load circuit l, sumcient current flows through the voltage regulating field winding VRF to cause the dynamoelectric machine 5 to generate the proper opposing voltage to maintain the load circuit voltage at the predetermined value; As the battery4 becomes discharged and its terminal voltage decreases, the load circuit voltage tends to decrease so as to decrease the voltagedrop between the adjustable contact 4| and the common connection 32 thereby causing less current to flow through the voltage regulating winding VRF, which in turn causes the dynamoelectricmachine' 5 to generate less opposcharge value, the voltage drop between the adiustable contact 4i and the common connection 32 decreases below the voltage drop across the resistors RHVR. and as so that the current now flows in the opposite direction through th exciter voltage regulating field winding VRF to reverse the polarities of theexciter 20 and the dynamoelectric machine 4 and thereby cause the voltage of the dynamoelectric machine I to boost the battery voltage an amount dependent upon the battery voltage.

What we claim as new and desire to secure by Letters Patent the United States is:

1. In a battery charging system, comprising a battery, a direct current supply circuit, and a dynamoelectric machine connected between said supply circuit and battery, a regulating arrangement for controlling the excitation of said machine comprising an exciter for said machine having a field winding, means for energizing said exciter in response to variations in the load circuit voltage, a constant voltage source, a resistor'connected in a circuit across said source and having a point thereof connected to one side While the battery 4 is supplying current to the load circuit l, the output current from the battery 4 is prevented irom exmeeding a predetermined value by the how or current through the current limiting field winding CLF. When the battery discharging current tends to exceed this predetermined value, the voltage drop across the resistor it exceeds the voltage drop between the common connection 32 and the adjustable contact 43, so that current fiows through the halfwave rectifier 44 and the field winding CLF in such a direction as to increase the excitation of the exciter ill and of the dynamoelectric machine I it the voltage regulating field winding VRF is so energized that the voltage of the machine 5 is opposing the battery volt ge and so as to decrease the excitation of the exciter and or the dynamoelectric machine 5 it the voltage regulating field winding VRF is so energized that the voltage or the machine I is in the same direction as the battery voltage. The current that flows through the current limiting field winding CLF also fiows through the portion oi the resistor ll between the common connection I! and the adiustable contact 4! in such a direction as to effect an increase in the volt ge drop across this portion of the circuit connected to the constant voltage generator Ii and a decrease in' the voltage drop across the resistors RHVR and ll. Consequently, when the output current or the battery 4 exceeds a predetermined value, the excitation of the voltage regulating field winding VLF is also varied to control the voltage of the machine I in the proper manner to decrease the current output irrespectively of the, polarity of the machinel.

It, while the battery 4 is supplying the load circuit I, voltage is restored to normal across the main supply circuit 2 so that the contactsllor the normal voltage relay NVR are closed, the

changes and modifications will be obvious to those skilled in the art, and we, therefore, aim in the appended claims to cover all such changes and modifications as fall within the truespirit and scope of our invention.

of said battery, a unidirectional current conducting device, a second resistor connected across said battery, and 'an opposing field winding on said exciter connected in series with said unidirectional current conductingv device between po nts on said resistors whereby current fiows through said opposing field windingonly when the voltage across said second resistor exceeds a predetermined value; p

2. In a battery charging system, comprising a battery, a direct current supply circuit, and a dynamoelectric machine connected between said supply circuit and battery. a regulating arrangement for UOUQOlliii the excitation or said machine comprising an exciter i'or said machine having a new winding, means ior energizing said exciter in response to. variations in the load circuit voltage, a irect current source having a constant potential, a resistor, a circuit including said resistor connected across said source, a connection between said last mentione circuit and one side of said cattery, a second resistor connected ac-oss said battery, a unidirectional current conducting device, and an opposing field winding on said exciter connected in series with said tundii'ectional'current conducting device between points on said resistois wiieieoy current flows through said opposing field winding only when the voltage across said resistor exceeds a predetermined value.

3. In a battery charging system,,comprising a battery, a direct current supply circuit, and a dynamoelectric machine-connected between said supply circuit and battery, a regulating arrangev ment for controlling the excitation of said ma- 4. In a battery charging system, comprising a battery, a direct current supply circuitian'd a dynamoelectric machine connected between said supply circuit and battery, a regulating arrangement for controlling the excitation of said machine comprising an exclter for said machine having a field winding, means for energizing said exciter in response to variations in the load circmt voltage, a constant voltage source, a resistor connected across said battery, a second resistor connected in series with said supp y circuit and said battery, an opposing field winding on said exciter, and means for energizing said opposing field winding in response to a predetermined relationship between the voltage ofsaid constant voltage source and the sumof the voltage drops across saidresistors. r

5. In abattery charging system, comprising a battery, a direct current supply circuit, and a dynamo-electric machine connected between said supply circuitand' battery, aregulating arrange: ment for controlling the excitation of said machine comprising an exciter for said machine having a field-s winding, means for energizing said exciter in response to variations in the load circuit voltage, a direct current sOllrCe having a'constant potential, a resistor, a circuit including said resistor connectedacross said source, a second resistor connected across said battery, a third resistor connected in series with said supply circuit and said battery, acommon connection between said first andthirdresistors, a unidirectional current conducting device, and an opposing field winding on said exciter connected in series with said unidirectional current conducting device between points on, said'first and third resistors whereby current flows through said opposing field winding only when the charging current is being supplied'to said battery and the Voltage drop between said common connection and the-point on said second resistor to which said opposing field winding is connected exceeds the voltage drop between said common connection and the point 'ofisaidfirst resistor to which said opposing field winding is connected.

8. In' a direct current system comprising a load circuit, a primary source connected across said load circuit,-and a dynamoelectric machine connected between saidload circuit and said battery, a regulating arrangement for controlling the excitation of said machine comprising an exciter for said machine having a field winding, means for energizing said field winding in response to vanations in the load circuit voltage, a direct current source having a constant voltage, a resistor, a circuit including said resistor connected across Said constant voltage source, a second resistor connected in series with said battery and load circuit, a unidirectional current conducting device, a second field winding on said exciter connected in series with said unidirectional current conducting device between predetermined points on said resistors, and another electric connection between said resistors whereby current fiows through said second field winding only in response to the current through said second resistor, ex-

' ceeding a predetermined value in a predetermined direction.

7. In a direct current systemcomprisinig a'load circuit,- a primary source connected across said load circuit, and a dynamoelectric machine connected between said load circuit and said battery, a regulating arrangement for controlling the excitation of said machine comprising an exciter for said machine having a field winding, means for energizing said field winding in response to variations in the load circuit voltage, a direct ourrent source having a constant voltage, a resistor,

a circuit including said resistor connected across said constant voltage source, a second resistorv I connected in series with said battery and load circuit, a unidirectional current conducting device; a second field winding on said exciter con- "nected in series with said unidirectional current conducting device between predetermined points on said resistors, and another electric connection between said resistors whereby the voltage drop across said second resistor is in the proper dire'c-- tion and of the proper magnitude to cause current to fiow through said second field winding in a direction to decrease the net excitation of 'said .exciter only when the charging current to said citation of said machine comprising an exciter for i said machine havinga field winding, means for energizing said field winding in response to variations in the load circuitvoltage, a direct current source having a constant voltage, a resistor, a circuit including said resistor connectedacrossisaid constant voltage source, a second resistor connected in series with said battery and load'circuit, a unidirectional currentconducting device, a sec-v 0nd field winding on said exciter connected in series withsaid unidirectional current conducting device between predeterminedpoints on said resistors, and another electric connection between said resistors whereby the voltage drop across said secondv resistor is in the proper direction and or the proper magnitude to cause current to flow through said second field winding in a predetermined direction only when the discharging current from said battery exceeds a predetermined value. 1

9. In a direct current system comprising 3. 10a

circuit, a primary-source connected across said load circuit, and a dynamoelectric machine connected between said load circuit and said battery, a regulating arrangement for controlling the excitation of said machine comprising an exciter -for said machine, a direct current source having a constant voltage, a resistor, a circuit including said resistor connected across said constant voltage source, a second resistor connected acrcsssaid load circuit, a field winding for said exciter connected between predetermined points of saidresistor, and an electric connection between said first mentioned resistor and said load circuit whereby the current through-said field winding depends upon the variations, in the load circuit voltage relative to the voltage irop across said first mentioned resistor.

10. In a direct current system comprising a load circuit, a primary source connected across saidload circuit, and a dynamoelectric machine connected between said load circuit and said battery, a regulating arrangement. for controlling the excitation of said machine comprising an exclter for said machine,-a direct current source having a-constant voltage, a resistor, a circuit includin said resistor connected across said constantvoltage source, a second resistor connected across said load circuit, a, field winding for said exciter connected between predetermined points of said resistor, an electric connection between said first mentioned resistor andlsaid load circuit whereby the current through said field winding depends upon the variations in thelload circuit voltage relative to the voltage drop across said first mentioned resistor, a third resistor consaid load circuit, and a dynamoelectric machine connected between said load circuit and said batterY, a regulating arrangement for controlling the excitation of said machine comprising an exciter for said machine, a direct current source having a constant voltage, a. resistor, a circuit including said resistor connected across said constant voltage source, a second resistor connected across said load circuit, a field winding for said exciter connected between predetermined points of said resistor, an electric connection between said first mentioned resistor and said load circuit whereby the current through said field winding depends upon the variations in the load circuit voltage relative to the voltage drop across said first mentioned resistor, a third resistor connected in series with said battery and load circuit, a unidirectional current conducting device, and a second field winding for said exciter connected in series with said unidirectional current conducting device between predetermined points on said resistors whereby the voltage drop across said second resistor is in the proper direction and of the proper magnitude to cause current to fiow through said field winding and a portion of said first resistor in a direction to decrease the net excitation of said exciter only when the charging current to said battery exceeds a predetermined value.

12. In a direct current system comprising a load circuit, a primary source connected across said load circuit, and a dynamoelectric machine connected between said load circuit and said battery, a regulating arrangement I or controlling the excitation of said machine comprising an exciter for said machine, a direct current source having a constant voltage, a resistor, a circuit including said resistor connected across said constant voltage source, a second resistor connected across said load circuit, a field winding for said exciter connected between predetermined points of said resistor, an electric connection between said first mentioned resistor and said load circuit whereby the current through said field winding depends upon the variations in the load circuit voltage relative to the voltage drop across said first mentioned resistor, a third resistor connected in series with said battery and load circuit, a unidirectional current conducting device, and a second field winding for said exciter connected in series with said unidirectional current conducting device between predetermined points on said reslstors whereby the voltage drop across said second'resistor is in the proper direction and of the proper magnitude to cause current to fiow through said field winding and a portion of said first resistor in a. direction to charge the excitation of said exciter in the proper manner to decrease the battery output only when the discharging current from said battery exceeds a predetermined value.

13. In a direct current system comprising a load circuit, a primary source or current connected to said circuit, a storage battery connected across said load circuit, and a. dynamoelectric machine connected between said load circuit and said battery, a regulating arrangement for controlling the excitation of said machine comprising an xciter for said machine having a field winding, means for disconnecting said primary source from said load circuit in response to the flow of current from said battery to said primary source, a direct current source having a constant voltage, a resistor, a circuit including said resistor connected across said constant voltage source, a second resistor connected across said load circuit, a field winding for said exciter, means controlled by said disconnecting means for connecting said-field winding between two predetermined points on said resistors when said primary source is connected to said load circuit and between two other predetermined points on said resistors when said primary source is disconnected from said load circuit, and an electric connection between said first resistor and said load circuit whereby the current through said field winding depends upon variations in the load circuit voltage relative to the voltage drop across said first resistor.

14. In a direct current system comprising a load circuit, a primary source of current connected to said circuit, a storage battery connected across said load circuit, and a dynamoelectric machine connected between said load circuit and said battery, a regulating arrangement for controlling the excitation of said machine comprising an exciter for said machine having a field winding, means for disconnecting said primary source from said load circuit in response to the fiow of current from said battery to said primary source, a direct current source having a constant voltage, a resistor, a circuit including said resistor connected across said constant voltage source, a second resistor connected across said load circuit, a field winding for said exciter, an adjustable contact on each resistor, means controlled by said disconnecting means for connecting said field winding between said adjustable contact on said first resistor and a predetermined fixed terminal of said second resistor when said primary source is connected to said load circuit and between said adjustable contact on said second resistor and a predetermined fixed terminal of said first resistor when said primary source is disconnected from said load circuit, and an electric connection between said first resistor and said load circuit whereby the current through said field winding depends upon variations in the load circuit voltage relative to the voltage drop across said first resistor.

BURR S. WEAVER. DONALD E. GARR. 

